Deletion of a DNA sequence in eight of nine families with X-linked ichthyosis (steroid sulphatase deficiency).

Deficiency of steroid sulphatase (STS) is associated with ichthyosis, with failure of the placental production of oestriol in late pregnancy and with difficulties in childbirth. The STS gene has been localised by deletion mapping to the distal tip of the snort arm of the X chromosome, and is of interest in that it appears to escape X-inactivation. We have constructed an X-specific DNA library and screened it for single copy DNA sequences which lie at the distal end of Xp. The sequence GMGX9 was found to map in the interval Xp22.3-pter and to detect a frequent HindIII polymorphism. We have used GMGX9 in linkage studies in families with classical X-linked ichthyosis and this has not only shown tight linkage with STS deficiency but has also revealed that the sequence is deleted in affected males in eight of nine families. GMGX9 is present in all of 26 normal male individuals so far examined. Our findings suggest that a high proportion of the mutations at the STS locus leading to enzyme deficiency are deletions, presumably generated by unequal cross-over events in female meiosis or by illegitimate X-Y interchange in male meiosis.     

Molecular analysis of X-linked ichthyosis in Japan

BACKGROUND: X-linked ichthyosis (XLI) is an inherited skin disorder caused by a deficiency of steroid sulfatase (STS). The gene and protein of STS were examined in 19 Japanese patients with XLI. RESULTS: In Western blotting analysis, no cross-reacting peptide was detected in the patients' placenta, although a single band (63 kD) corresponding to STS in a normal subject was observed. Southern blotting was performed using EcoRI digests of cellular DNA from 13 XLI patients and full-length human STS cDNA as a probe. Normal males had bands of 20, 15, 10, 9.0, 6.1, 4.2, 2.6, and 1.5 kb. Twelve of the 19 patients had only 20- and 1.5-kb bands. Only one patient had the same band pattern as that of normal males. The STS gene was analyzed by PCR in 6 of the 19 patients. PCR amplification products were sequenced to analyze the STS gene. Two cases with one-base change in the STS gene and variation in amino acids H444R and E560P were found. Mutant STS cDNA was transfected into COS-1 cells and the STS enzyme activity was assayed. The enzyme activities were less than the minimum detection value of the detection system. CONCLUSIONS: These results suggest that XLI is mainly caused by an extensive deletion of the STS gene and that the PCR method is useful for detection of STS point mutations.     

Ultrastructural distinction of autosomal dominant ichthyosis vulgaris and X-linked recessive ichthyosis

Summary In autosomal dominant ichthyosis vularis ultrastructural studies have revealed a severe disturbance of keratohyalin synthesis by which this entity may clearly be distinguished from X-linked ichthyosis.

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Zusammenfassung Die autosomal dominante Ichthyosis vulgaris ist durch einen Defekt der Keratohyalinsynthese gekennzeichnet, der erstmals elektronenmikroskopisch nachgewiesen wurde und eine klare Unterscheidung von der klinisch ähnlichen X-chromosomal rezessiven Ichthyosis erlaubt.

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Supported by the Deutsche Forschungsgemeinschaft, Sonderforschungsbereich Klinische Genetik, SFB 35/5 and 7.     

X-linked recessive ichthyosis. Enzymatic diagnosis of affected males and female carriers

Steroid sulfatase deficiency (SSD) is a sex-linked disorder characterized clinically by generalized X-linked ichthyosis. We report a study of 10 families where the clinical diagnosis of this disorder was confirmed by measuring arylsulfatase C and steroid sulfatase (STS) in cultured skin fibroblasts and/or leukocytes of patients and heterozygotes. The optimal conditions for these enzymatic determinations were determined. Our data indicate that STS measurement is a reliable test for SSD diagnosis, either in fibroblasts or in leukocytes. For the detection of heterozygotes, several enzymatic determinations in different cell types are required.     

Linkage analysis in X-linked ichthyosis (steroid sulfatase deficiency)

Summary Linkage analysis has been carried out in nine unrelated families segregating for X-linked ichthyosis (steroid sulfatase deficiency) using seven polymorphic DNA markers from the distal Xp. Close linkage was found between the disease locus and the loci DXS16, DXS89, and DXS143. In all families except one, Southern hybridization with the human steroid sulfatase cDNA and GMGX9 probes showed a deletion of corresponding loci in affected males. Three patients belonging to the same family had no evident deletion with either of the two above-mentioned probes. None of the other six DNA loci included in the linkage analysis were found to be deleted.     

两个常染色体显性遗传寻常性鱼鳞病家系致病基因的定位

为了对寻常性鱼鳞病的致病基因进行定位, 收集了2个湖南寻常性鱼鳞病家系, 采集外周血, 提取基因组DNA, 采用1号染色体和10号染色体上2个已知寻常性鱼鳞病位点的微卫星标记对这两个家系进行基因分型和连锁分析。结果显示, 寻常性鱼鳞病家系1的致病基因位于D1S498(1q21)附近, 与已知定位区间重叠; 寻常性鱼鳞病家系2的致病基因位点与已知的寻常性鱼鳞病位点不连锁, 可能存在新的致病基因位点。     

X-linked mental retardation with the fragile X. A study of 15 families

Summary The coinical and cytogenetic features of 15 families with mental retardation linked to the fragile site on the X chromosome are presented.The 15 propositi were all prepubertal, and one was a girl. Although the clinical picture varied in severity, it was sufficiently constant to suggest the diagnosis from the facial features and the encephalopathy with language retardation and disturbed behavior. Macroorchidism was not seen before puberty.The fragile X chromosome was found in seven of the nine mothers studied and in two mildly retarded sisters and has also been demonstrated in fibroblasts in eleven subjects with the abnormality.Supported by grants from INSERM (ATP 79-110)     

Deletion pattern of the STS gene in X-linked ichthyosis in a Mexican population

BACKGROUND: X-linked ichthyosis (XLI) is an inherited disorder due to steroid sulfatase deficiency (STS). Most XLI patients (>90%) have complete deletion of the STS gene and flanking sequences. The presence of low copy number repeats (G1.3 and CRI-S232) on either side of the STS gene seems to play a role in the high frequency of these interstitial deletions. In the present study, we analyzed 80 Mexican patients with XLI and complete deletion of the STS gene. MATERIALS AND METHODS: STS activity was measured in the leukocytes using 7-[(3)H]-dehydroepiandrosterone sulfate as a substrate. Amplification of the regions telomeric-DXS89, DXS996, DXS1139, DXS1130, 5' STS, 3' STS, DXS1131, DXS1133, DXS237, DXS1132, DXF22S1, DXS278, DXS1134-centromeric was performed through PCR. RESULTS: No STS activity was detected in the XLI patients (0.00 pmoles/mg protein/h). We observed 3 different patterns of deletion. The first two groups included 25 and 32 patients, respectively, in which homologous sequences were involved. These subjects showed the 5' STS deletion at the sequence DXS1139, corresponding to the probe CRI-S232A2. The group of 32 patients presented the 3' STS rupture site at the sequence DXF22S1 (probe G1.3) and the remaining 25 patients had the 3' STS breakpoint at the sequence DXS278 (probe CRI-S232B2). The third group included 23 patients with the breakpoints at several regions on either side of the STS gene. No implication of the homologous sequences were observed in this group. CONCLUSION: These data indicate that more complex mechanisms, apart from homologous recombination, are occurring in the genesis of the breakpoints of the STS gene of XLI Mexican patients.     

Memory,mood and associated neuroanatomy in individuals with steroid sulphatase deficiency (X-linked ichthyosis)

Steroid sulphatase (STS) cleaves sulphate groups from steroid hormones, and steroid (sulphate) levels correlate with mood and age-related cognitive decline. In animals, STS inhibition or deletion of the associated gene, enhances memory/neuroprotection and alters hippocampal neurochemistry. Little is known about the consequences of constitutive STS deficiency on memory-related processes in humans. We investigated self-reported memory performance (Multifactorial Memory Questionnaire), word-picture recall and recent mood (Kessler Psychological Distress Scale, K10) in adult males with STS deficiency diagnosed with the dermatological condition X-linked ichthyosis (XLI; n = 41) and in adult female carriers of XLI-associated genetic variants (n = 79); we compared results to those obtained from matched control subjects [diagnosed with ichthyosis vulgaris (IV, n = 98) or recruited from the general population (n = 250)]. Using the UK Biobank, we compared mood/memory-related neuroanatomy in carriers of genetic deletions encompassing STS (n = 28) and non-carriers (n = 34,522). We found poorer word-picture recall and lower perceived memory abilities in males with XLI and female carriers compared with control groups. XLI-associated variant carriers and individuals with IV reported more adverse mood symptoms, reduced memory contentment and greater use of memory aids, compared with general population controls. Mood and memory findings appeared largely independent. Neuroanatomical analysis only indicated a nominally-significantly larger molecular layer in the right hippocampal body of deletion carriers relative to non-carriers. In humans, constitutive STS deficiency appears associated with mood-independent impairments in memory but not with large effects on underlying brain structure; the mediating psychobiological mechanisms might be explored further in individuals with XLI and in new mammalian models lacking STS developmentally.     

Sex ratio in Down syndrome. Studies in patients with confirmed trisomy 21

Male to female ratio (sex ratio, SR) for 1,329 liveborns with Down syndrome and for 178,160 newborns from the general population of St. Petersburg, Russia was determined as a function of a mother age. Male prevalence (an overall SR of 1.24) was found in children with all trisomy 21 variants except the cases with mosaicism (the ratio of 0.88). The most expressed male predominance was determined in children of mothers aged 20-24 years, where SR was 1.73 in the total group (p = 0.00003) and 1.61 in the cases with free trisomy (p = 0.0007). Some hypotheses concerning the male accumulation in this group are discussed including a suggestion that the SR deviations from the population value 1.06 might be due to different contribution of paternal chromosomal non-disjunction during spermatogenesis.     

Sex ratio trajectory in mouse

Skewing of the sex ratio towards males occurs in humans. The possible explanation for excess male births could be a preference for Y-bearing sperm at fertilization and/or selective elimination of female embryos during pregnancy. In this study, we have tested the sex ratio in the preimplantation embryo (2–3 cells stage/closest possible primary sex ratio), the post-implantation embryo (day E7.5), and at birth (secondary sex ratio) on a homogenous (genetic, environmental, and dietary) population of mice to ascertain the biological reason i.e., male preference at fertilization or female elimination during pregnancy or both. Primary sex ratio on early preimplantation embryos (2–3 cells stage) was studied on 598 embryos and secondary sex ratio (at birth) on 721 pups using PCR-based sexing (both X & Y chromosome-specific) besides sex ratio of 80 post-implantation embryos (day E7.5). We have also investigated whether the fat content (high & low) of the diet affects the sex ratio. We observed a skewed sex ratio (more female) in preimplantation embryos (0.436; 95 % CI 0.39, 0.48), and post-implantation embryos (0.462; 95 % CI 0.35, 0.57) but reverse skewing (more male) at birth (0.539; 95 % CI 0.5, 0.58). We also observed that high-fat diet promoted male sex ratio at birth (0.657; 95 % CI 0.57, 0.74) whereas a low-fat diet had the opposite effect (0.46; 95 % CI 0.36, 0.56) but no effect at fertilization (2–3 cells stage embryos). This indicates selective elimination of female embryo and fetus throughout pregnancy in mice, more so with a high-fat diet.     

Sex ratio in Down syndrome

Data from 55 publications providing the sex ratio (SR), i.e. ratio between male and female cases of Down syndrome (DS), are presented. In general, SR was skewed toward an excess of males in the majority of studied populations, either in populations with a high level of cases ascertainment (epidemiological studies) or in selected groups. No significant correlation involving the age of either patients or mothers was found. Some other factors which might influence the sex ratio in DS at birth are mentioned. Meta-analysis of data from epidemiological studies suggests the phenomenon is not restricted to free trisomy 21 alone but appears in translocation cases, both in mutant and inherited translocation carriers (SR = 1.31 and 1.36, respectively). In contrast to nonmosaic 47, +21 cases, where SR is close to 1.3, an excess of females was observed in mosaics 46/47, +21 (SR = 0.83). No male predominance was found among patients with DS not tested cytogenetically (SR = 0.98), which may be explained by female predominance in false-positive cases. In populations with a fraction of clinically diagnosed cases of 30% and over, SR has intermediate value of 1.1. The ratio showed a tendency to increase since 1940's, reaching a mean value of 1.35 in 1980's varying from 1.3 to 1.62 in different populations), which might be a consequence of the growing use of karyotyping to confirm diagnosis and of a real increase in proportion of males. In the 1990's, the ratio fell to 1.22 varying from 1.03 to 1.27. As SR is assumed to reflect a proportion of paternal contribution, the discrepancy between the proportions of paternal errors in cytogenetic studies on parental origin of the extra chromosome (24% in the 1980's) and in molecular studies (5-10% in the 1990's) discussed in the literature might be explained by temporal changes alone. Genetic mechanisms of male predominance in trisomy 21 are reviewed, among them models for joint segregation of chromosome 21 and Y chromosome in spermatogenesis, and the chromosome 21 nondisjunction during 2nd meiotic division of oogenesis caused by Y chromosome-bearing spermatozoa.